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No. 620,|83. Patented Feb. 28, I899. l. RISLEY &. V. F. LAKE.

TYPOGRAPHIG MACHINE.

(Application filed Aug. 6, 1892.)

(No Mudl.) I I4 Sheets-Sheet I.

No. 620,!83. Patented Feb. 28, I899.

I. BISLEY 81. V. F. LAKE.

TYPOGRAPHIC MACHINE.

(Application filed Aug. 6, 1892.

(No Model.)

[4 Shaats-$haet 2.

Patented Feb. 28, I899.

I. BISLEY & v. F. LAKE.

TYPOGRAPHIO MACHINE.

(Application filed Aug. 6, 1892.)

I4 Sheets-4M0! 3.

(No Model.)

'Wz/Zrwsseas Jnvaviard Isa/we RrleZa 8p W VI/W1 1.50%.

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(No Model.)

Patented Feb. 28, I899. I. HISLEY &. V. F. LMKE.

TYPOGRAPHIO MACHIFQE.

(Application flied Aug. 6 1892.)

I4 Sheets-8heet 4.

Witnessas No. 620,l83. Patented Feb. 28, I899.

' I. BISLEY & V. F. LAKE.

TYPDGRAPHIC MACHINE.

(Application filed Aug. 6, 1892.)

I4 sheets-sheet 5.

(Ho Modal.)

Wzlincsses Key & moerdiizm 3! flit-arrays m T m J Paiented Feb. 28, i899.

!. RISLEY & V. F. LAKE.

TYPOGBAPI-IIC moi-nus.

(Application filed. Aug. 6, 1892.)

I4 Sheets-Sheet 6.

56H VC 067w E Lake w oea-se Patented Feb. 28, I899.

I. BISLEY & V. F. LAKE.

TY'POGBAPHIG MACHINE.

l4 Sheets-Sheet 7.

(Applicutioq filed Aug. 6,.1892.)

(No Model.)

Wain/eases Patented Feb. 28, I899. I. RISLEY &. V. F. LAKE.

TYPOGBAPHIG MACHINE.

(Application filed Aug. 6, 1892.)

(No Model.)

WILD-1166666. Cl 1).

a 9 w Rm 2 B .r d e t n e t a P Fm K A L F V Y E L m on 2w m 2 6 0 N TYPOGRAPHIG MACHINE.

(Application filed Aug. 6, 1892.)

I4 Sheets-Sheet 9.

(No Model.)

Witness cs Inventors J6me Risk 60 5/ ale 6 by their" Jltlvr m No. 620,|83. Patented Feb. 28, 1899.

1 I. RISLEY 81. V. F. LAKE.

TYPUGRAPHIG MACHINE.

(Application filed Aug. 6, 1892.)

I4 Sheets-Sheet ID.

(No Model.)

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No. 620,!83. Patented Feb. 28, I899. I. RISLEY &. V. F. LAKE.

TYPOGRAPHIC MACHINE.

(Application filed Aug. 6, 1892.)

I4 Sheets-Shut II.

(No Model.)

lnlleniars Isaac Rvjsleg & VI); E Lake, 5y their Mar 6" N0. 620,l83. I Patented Feb. 28, I899. I. RISLEY &. V. F. LAKE.

TYPOGRAPHIG MACHINE.

(Application filed Aug. 6, 1892.)

I4 Sheets-Sheet I3.

(No Model.)

Invaders: JjSnuw Risky 8c yvtcsnZ F'Lake FIG/.62

Wnksses: (l1).

Patented Feb. 23, I899.

I4 Sheets-Sheet I4.

jifgaaa BISLEY & V. F. LAKE. TYPOGRAPHI'C MACHINE. (Applicafiqn filed Aug. 6, 1892.)

(No Modell) FIG .36,

y C llrwervfi Flake Inventor s JS aac "7B (is Ze me ayday-Z Improvements in Typographic Machines, of

automatic means.

I dated August 10, 1897, granted to Isaac Risjustification inthe final. representation or line or recording or registering the units to 'final impression or representation consisted riage, impressing mechanism, and means for UNITED "ST TES.

PATENT OFFICE.

IISA'AC RISLEY A D VINCENT F. LAKE, OFPLEASANTVILLEINEW JERSEY, AssIeNoRs, BY MESNE, ASSIGNMENTS, o JOSEPH n. BORTON, TRUSTEE.

TYPOGRAPHIIC MACHINE.

srncxrrcarron i brming part of Letters Patent No. 620,183, dated February 28. 1899.

" Application and lu uas, 1892.

To all whom it may concern: Y

Be it known that we, ISAAC RISLEY and VINCENT F.- L KEfcitizens' of the United States, and residents of Pleasantville, Atlantic county, New Jersey, have invented certain which the following is a specification.

Our present invention is in the nature of an improvement upon the invention of a machine for typographic purposes forming the subject of the Letters Patent No. 588,087,

ley.

One of the importantfeatures of improve" ment consists in the provision of means whereby the ju tificatio-n of the line governed by the unit rec rd or registeris efiectedby It should be understood, however, that many features of our present invention are applicable to and can be employed in typographic machines in which'the final impression is not effected automatically.

A further important feature of our present invention consists in means for automatically closing the line of matter composed.

'As in the Risley invention, our present ma chine is shown as embodying a keyboard mechanism or composing-action, means for producing a preliminary representation, and means for measuring the matter forming a govern the final justified representation in the word-spaces which are also registered. In the machine specifically illustrated in the Risley patent punched paper is shown as employed for the, preliminary representation, whereas in they machine illustrated inthis aptionally'inivheels or disks are employed for the purpose. Inthe machine illustrated in the Risley patent the means for producing .the

of mechanism in the natureof'a type-writer, whereas the machine herein specifically illustrated and described is primarily designed for matrix-making and employs a matrix-carsuccessively locating the dilferent punches of the different characters to be successively im- Serial No. 442,334. (No model.) M

pressed upon the matrix. Our improvements are not, however,.'l imited to matrix-making machines, but are also applicable in the maih to other typographic machines, such as typecasting, type-setting, 'or type -writing mainvention. Fig. 2 is a side view, looking in the direction of the arrow, Fig. 1. a longitudinal sectional view on the line 0 0, Fig. 1. Fig 2 is a view, drawn to an enlarged scale, of a part'fof the escapment for the right-hand pin-wheel. verse sectional view on the line 1 2, Fig. 1. Fig. 4 is a transverse sectional view on the line 3 .4, Fig. 1. Fig. 4 is a transverse sectional view on the line '5 '6, Fig. 1.

riage frame. Fig. ,6 is an enlarged sectional view on the line 7'8,Fig. 1. Fig. 7 is aplan view in detail showing a number of the keys-and their connections, the balanceof the keyboard being removed to avoid confusion. In this view certain parts are shown, which for the sake of clearness have beenjomitted from x I Fig. 8 is a side view of Fig. 7. Fig. '8 is an enlarged plan view of a portion of Fig. 7. Fig. 9 is a view of the vertical char- Fig. 10 is a plan Fig. 1.

actor-locating mechanism. view of Fig. 9. Fig. 11 is a side view of the vertical locating-cam, being a section on the line 11 12, Fig. 1-. Fig. 11 is a view o f -,the

Fig. 3iis a trans-. v

Fig. 5 is I a transverse sectional view of the matrix-car back of the locating-cam. Fig. 11 is a 'sec-, L

tional view of the locating-cam. Fig. 12 is an enlarged detailed elevation of the punchcal-pier. .Fig. 13 is a plan view of Fig. 12. Fig v 14 is a view of the punch-frame "which forms .part of the punch-carrier. Fig. 15 is a plan view of Fig. 14. Fig. 16 is a viewshowing one of the matrix-punches. Fig- 17 is a diagram showing the arrangement of the keyson the keyboard and the arrangement of the matrix-punches in the punch-carrier. Fig. 18is a diagram illustrating a line of composition upon thecharacter-representing mechanism. Fig. 19 is a diagram illustrating the registration of the matter composed, as in Fig. 18,

upon the unit composition-register and illus-. "trating the matter after it has been j ustified roe shaft.

'nection when in a minus position.

strikers alluded to above.

2 Wind by the automatic mechanism. Figs. 20 and 21 are skeleton plan views showing the connections between the character-keys and the punch-carrier, the automatic j ustifying mechanism being omitted in these views. Fig. 22 is a diagram of the unit register feed rock- Fig. 23 is a perspective view of the punch-carrier frame. Fig. 24 is a side view of the-punch-carrier. Fig..25 is a skeleton plan view illustrating the automatic justifytion on the line 9 10, Fig. 25. Figs. 27, 28, and 29 are'di'agrams illustrating the justifyingarm and its connections when in the plus position. Figs. 30, 31, and 32 are diagrams illustrating the justifying-arm and its con- Figs. 33,34, and 35 are sectionalelevations, similar to Fig. 26, with parts removed to illustrate more clearly certain details of the mechanism. Fig. 36 is a detached plan view of the j ustifying-arm. Figs. 37 and 38are sectional views of details hereinafter referred to.

In order to simplify the description of the parts and the operation of our improved machine, we have used the following terms to designate different sections of the machine, and the word action found in the specification is the same as used when referring to the action of apiano. We will take the terms up in the order that they appear in the description: v

First, the composing-action: This includes; the keyboard, the keys, the strikers'for projecting the pins upon the pin=wheels, andthei lever mechanism between the keys and the.

strikers.

Second, the character-representing IDGCh-i anism: This in the present instance is shownas a shaft on which are two pin-wheels having concentric series of holes in whichare' suitable pins which can be projected by the The shaft carrying the wheels is given a positive intermittent forward feed bya feed-pawl, which, however, is thrown into and out of gear-by intervening mechanism controlled by the keys.

Third, the space-representing mechanism: This mechanism consists ofa number of rows of pins upon one of the pin-wheels. In the present instance there are three rows of pins indicating five-unit measurements. We would state that each character of our machine has for its space occupied upon the matrix-sheet a predetermined number of units,

as two units for the narrow characters-such as f, l, and i--three units for such characters as e and s, four units for such letters as a, b, and d,five units for the letters to, W, and M, 850., and that the above-mentioned rows of pins are used to represent the unit widths of said charac-' ters, and in addition a space between words.-

'We invariably represent from composition at the keyboard a word-space of three-units width, which is increased or diminished, if.

.necessary, by the justifying mechanism,

which will project certain pins or depress the three-unit-space pins to lengthen or shorten the composed line prior to impression upon the matrix-sheet.

Fourth, the unit composition-register: This consists of a dial, a pointer, a signal and a connection with the keyboard, so that every stroke upon the keys by the operator will indicate upon the register the number of units that the character or word space occupies. This mechanism acts upon the automatic justifying mechanism when the dial has reached a certain point, and the dial also indicates the number of units in a line. The automatic justifying mechanism, however, justifies the line.

Fifth, the character-locating mechanism: This includes the mechanism acted upon by the individual character-punches in proper position to be impressed into the matrixsheet, and consists of a power-shaft having upon it two multiple cams, each operating an independent traveler, and switch mechanism acted upon by the character-pins, by which the traveler of each cam is directed into a given groove, the travelers being so geared to the character-punch carrier'that one cam will give the vertical movements to the carrier and the other cam-will give the lateral movements to the carrier. Thus any characterpunch can be located either by the single movement of one of these travelers or by the combined movement of the two.

Sixth, the automatic justifying mechanism, which includes the justifying-arm, the

vices for uncovering the pins carried ,by the arms, the mechanism controlled by the pins,

the strikers and their connections by which the pins on the pin-wheel are readjusted, so as to add orsubtract the number of unitssufficient to justify the line, the line in the present instance being one hundred and forty four units in length.

Seve'nth,the impressing mechanism: This simply consists in the present instance of a plunger having intermittent motion, which acts upon the selected character-punch to force it into the matrix-sheet.

'Eighth, the matrix-carrier: This consists of aframe upon which the matrix-sheet is mounted being given a justified unit-space movement and an intermittent line movement.

Ninth, the matrix-carrier feed: This includes mechanism for giving the proper unit movement to the matrix-sheet, and-in the present'instance consists of a ratchet-wheel having at least as many teeth as there are units in the justified line and lever mechanism for acting upon the ratchet-wheeh this e2o,1s3 I v ning of a new 1ine--and at the sametime" it acts upon the line-feed mechanism to feed the matrix one line and holds certain parts of the automatic justifying mechanism out of gear until the carriage is returned, when the parts are released and the feed-pawl thrown into gear, ready to commence a new line.

In describing the details of our invention we will, as much as possible, set forth the details of each section as described above, so

as to simplify the description. In order to give a clear understanding of the operation and object of our invention, we will now refer to the diagrams Figs. 18 and 19. I Fig. 18 is a diagram representing by inter: sectin g lines the different rows of pins on the pin-wheels and the black spots representing projected pins. In the present instance the left representin' pin-wheel has two rowsof character repre enting pins for vertically moving the punch-carrier, three rows of unit and space pins, and-one row termed the special space-pin row. The machine is so arranged that the smallest space is the one-unit space and the largest space a five-unit space;

but it will'be evident that the space-units may be increased in number without departing from our invention; We may in some instances use five rows of character and space unit-pins projecting the pins one distance; but in order to economize space in construction we reduce it to three rows, the first row representing one unit, and by pushing the pins of the second row half-way out two units are represented, and'by pushing the same pins outthe fulldistance three-units are represented. When the third-row pins are projected one-half the distance, four units are represented, and if these pins are projected the full distance five units are represented, and. it will be understood that the normal word-space is three units, and this word-space can be contracted to one or two units, or it can be increased to four or five units.

It will be readily understood that whereit is desired to have but one distance movement of the representation-pins it is simply-necessary to increase the number of rows of pins and to operate them b'y'means similar to those used for operating the one-distance-m'ovement pins hereinafter referred to.

We would state here that while We have shown and described the five-unit measure: ment it will be understood that a machine wheel.

may be made to embody more or less units,

according to the unit division of the character. On the right representing-wheel we have two rows of character-representing pins for horizontally moving the punch-carrier, The third row of representing-pins gives a horizontal reverse movement to the punch-carrier, and the fourth row gives a reverse vertical movement to the punch-carrier,

. ,We would state here in order to avoid confusion hereinafter that by arranging the punch-carrier as shown, so that the punches always come to the center to press the matrixsheet, we use clutching mechanism for moving the carrier, one set of clutching mechan ism being used for the vertical movement, and one set of clutching mechanism being used for'the horizontal movement, and We so arrange the mechanism that one face of each clutch is normally in. gear. In the present instance the two clutch-faces, one for giving the downward motion to the carrier and the other for giving the left-hand horizontal motion, are normally in gear, and when it is required to give the upward motion or a right- .hand horizontal movement the clutches that are normally out of gear are thrown into gear by the projected pins on the third and fourth pin rows of the right-hand representing The fifth rowof pins on the right-' hand representing-wheel operate mechanism to return the matrix-carrier to its normal po-' sition to begin a new line. We have shown projected pins in this line, the-first pin reptoo resenting the completion of a prior line, and

the second pin represents the completion of the line shown represented in the diagram.

Before describing our method of justifying the matter set up we will refer to Fig. 19, which is a'diagram in which each unit of feed is represented. The normal length of line we have indicated as one'hundred and forty-four units; but we operate a signal when We reach one hundred and twenty-eight units or sixteen units short of the predetermined, standard line, thus leaving sixteen units in which to complete the line. it happens that when the signal is given we have a word that cannot be completed within the sixteen units above mentioned we are 'at liberty to run beyond the one hundred and forty-fourth unit-line a certain number of units, in the present instance sixteen. We

representing examples, the first representing aline falling short of the predetermined number of units, (one hundred and forty-four,) the second the former line justified, and the third line representing the matter extending beyond the predetermined number of un ts, and the fourth the third line j ustified. It willbe understood that this condition only occurs on the representing pin-wheel and on the. unitregistering dial and that the first line 1s identical with the matter represented by the black pins. (Shown in Fig. 18.) It will be noticed in referring again to Fig. 19 that the line s five Now if I Izo have'shown in this diagram four sets of lines units short. Consequently five units will have to be added to the wordspaces within'the line. In the present composition there are seVenord-spaces. Therefore we need only unit-pins already projected on the fourth row,

so that when the matter is transferred tothe matrix-sheet the word-space instead of being three units in length, as originally represented by the operator, will be four units in length, increasing the line as many units as the line was short. Thus the matter terminates at a given point of one hundred and forty-four units when impressed.

Turning now to the third line of the dia gram Fig. 19, we have an instance in which the' line composed is longer than the predetermined line of one hundred and forty-four units. We therefore contract the word-spaces by pushingin all of the three unit-word-space pins and projecting one-unit-space pin and three two-unit, making a deduction of thir-.

' .teen units in the full line, which will bring the line tothe predetermined standard of one hundred and forty-four units.

We would state here that the line very seldom falls short more than a few units or,

overruns more than a few units. We have shown 'an extreme case by insert-in g the word which in the diagram Fig. 19.

We will-now describe in detail the composing-action, referring particularly to Figs. 1, 2, 3, 6, 7, and s.

The composing-action, as will be under-' stood, comprises a keyboard, the levers and strikers which act upon the pins on the pin- .wheel, and the mechanism for operating the registerdial. Referring first to the keyboard, Figs. 1 and 17, it will be noticed that some of the letters are arranged on a vertical central line and some on a horizontal central line, these two lines crossing each otherat' the center of the keyboard, at which pointwe provide the space-key. These vertical and horizontal lines divide the keyboard into four sections, as shown in the diagram Fig. 17, and this arrangement is duplicated onthe punch-carrier, the punches being arranged identically in the same manner as the keys upon the keyboard, and as the punch-earrier is mounted vertically on the machine we.

:have deemed it best to use the terms vertical and horizontal in referring to the keyboard, so as to avoid confusion. The impressing mechanism is arranged directly opposite the center space on the'punch-carrier,

so that all the characters have to be brought to this point by certain movements, some.

plain and some compound, in order to be impressed into the matrix-sheet. All the characters on the central vertical line need only be moved in a vertical direction, while all the characters on the central horizontal line need be moved only in a horizontal direction; but the characters in the four blocks of sections have not only a vertical motion, but also a horizontal motion, as will be readily understood when we refer more particularly tothe details of the punch-carrier and to the mechanism for operating the same. i

Mounted upon the base-frame W of the machine is the keyboard A, Fig. 1, which can be constructed in any'suitable manner to allow of the free movement of the keys A to operateupon the lever mechanism. The key A is composed of a vertical round stem A", Fig. 2, with the lower portion reduced at one side, so as to form a shoulder A under which rests one of the transverse levers B, which extend from one side of the keyboard to the other and are journaled in bearings w. A

depression of any of thetransverse levers B,

with the exception of the central lever, which is placed in position not for the purpose of moving the punchcarrier, but for the purpose of operating the unit composition-regis-.

ter and operating the space representing mechanisnnwill initiate the movements which finally control the vertical movements of the punch-carrier.

It will be understood that the transverse levers B are not only utilized to operate the vertical movements of the punch-carrier, but also to operate upon the space mechanism and the unit composition-register. The longitudinal levers, which we will now refer to, simply operate upon the character representing mechanism, which in turn controls the horizontal movements of the punch-carrier. Directly under the stem A of each key is a lon gitudinaljlever B of a series, except under the keys on the central vertical line. The levers B are also journaled in suitable bearings w.

Before proceeding further with thedetails of construction we will state that while a number-of the levers B have three arms, one operating upon the character-representing pins, another upon the space-representing pins,'and the last one upon the registering mechanism, others of the levers have an additional arm for acting upon the vertical reverse-pins, as will be described in detail. The longitudinal levers B are each provided with arms for projecting the pins on the right-hand pin-wheel, and some of these levers have an additional arm for projecting the horizontal reverse-pins.

In order to simplify the construction, we will refer to the skeleton view,,Fig. 20, and follow out the movements of the several operations when the key having v upon it is depressed. This character is in the central vertical line, and in order to bring the chartoo - only operates upon the transverse lever B, as

it will be remembered that a lever B isomitted on the central vertical line.

- The journal B of the lever Bhas acharu acte'r-pin-operating arm B and'a space-pinoperating B The'arm B is forked at its lower end and passes over a shouldered rod B, which; on the depression will be moved in the direction of its arrow. The J arm B acts against r5 one of the shoulders on-the rod, as clearly shown in' Fig. 6. I As soon as the stroke is made aspring B7 returnsthe lever and its parts to their normal positionsready to receive the merit stroke. The rod B is connect ed to one arm of a bell-crank lever B Figs.- 20 and 8 the other arm'of the lever being connected to a rod 13", which in turn is con- ..nected to one arm of a pin-striker O, which is carried by a striker-frame O, as clearly shown-inFig. 3, This strikeracts upon the outer row of pins of the left-hand pin-wheel, which, it will 'be remembered, has two rows of I character-representing pins'D D, the outer, row being D and the inner row being D.

These pins D Dare mounted so as to slide im the holes in the left-hand pin-wheel E anid are retained in 'positionby friction mechan-l ism. (Not shown, as any of the ordinarydevices may be e ployed-snch, for instance, as a band bear'ng upon the several pins or friction mechanism carried by the pin itself.) We'wo uld state here that these character- 4 pins may be projected either of two distances.

(Indicated by dotted lines in Fig. 20.) For in:

40 stance, if the character-keymarkedFv, Fig.

20, is depressed its arm'B 'will move in space before striking the collar on the rod 13, Fig. 6. Consequently the pin-striker will be moved only one-half of its full distance, and conse- 5 quently the pin of the outer pin row will be projected to the intermediate dotted line, or. the first distance. These transverse rows of keys, Fig. 1, with the exception of the central row, are arranged in pairs. For instance,

5o the keys in therows -1- Iron each side of the central row project-the pins .of the outside row the. first distance and the 'keyrows 2 2 project the outside row of said pins the full distance, and the keys in the rows 3 3 pro-- 1 ject the pins in the second row the first distanee and the keys onj the rows 4 4 project the pins on the secpnd row the, full distance.- The keys onsthese third and fiou'rth transverse rows have arms B acting upona rod B (similar to the rod A which acts on the bellcrank lever B, connected by a link 13 to the striker C ,.Figs. 1 and 8".

It will be' understood, aspreviou'sly remarked, that the levers Band their connec- 6 5 tions only move the punch-carrier invertical' lines, as the'horjzontal movements of the punch-carrier are effected through the pins arm B and a'unit-registering arm;

on the right-hand pin-wheel The levers B above the central row of characters move 'their,'respective characters into position directly through the medium of the pins and the direct connections to t,he punch-carrier,

while the levers below the central line of characters not only project their respective pins inthe pin-wheel E, but aiso project pins in the vertical reverse-pin row on the'right-hand pin -wheel E, which jwe will describe hereinafter. t

g We will'nowdescribe one of the simplest horizontal movements by referring to one of the keys on the central transverse row marked e3 This key andall keys on the. central row have the same relation to the pins on'the pin-wheel E' as the key markedjv? and as thekeys on the vertical row have te the pinwheel E. Directly under all of the keys of the keyboard, with the exception of the central longitudinal row, are levers B, alluded to above. These levers are arranged in pairssimilar to the arrangement of the transverse 9o levers Bthat is, the levers 1 1, Fig. 20, are 'paired to' project' the pins onthe pin row D the first distance and the levers 2 2 are paired to project the pins on thefirst pin row D the full distance, while thelevers 3 3 are paired to'project the pins on the second pin .row'D the first distance and the levers 4 4 project the pins on the said pin ro'w D the full distance, so that if we press the letterfe it will act to project the pins'-in.the pin row D the too first distance the same as thelett'ermarked v operates in reference to the pins in the pin row D of the pin-wheel E.. The two out-.' side levers acted upon'by the'keys on the,-

longitudinal lines 3 and 40h each side of the I.

' central line, as before remarked. are pivoted in bearings 'w and-have arms B connected by a link B tte one arm of a bell-crank lever B which is mounted loosely upon the rock-.

shaft B a'dapted tobearings w w'on the 1 1o frameof. the machine, "as clearlyshown in Fig. 2. The other arm of this lever is con- 7 I .nected by a link B to a striker 0 The levers; B directly under the keys on "the longitudinal lines 3 4 on each side of a central 1 5 line are connected bya link B, Fig. 21,'to an under arm B secured to the rock-shaft B which passes up through the sleeve B1 alluded to above, and has an upper arm 13, Fig. 1, connected by alink B to the striker .120 0 which projects the pin on-the outside pin -row D on' the pin-wheel E. v g v In order to obtain the two movements of thepins from the levers B just described, we provide each lever with two steps, as clearly shown in Figs. 1 and20, one step beingnearer the fulcrum of-the lever than the other step andonest ep being under-one of the rowsfiof the keys and the other-step being under anotherrow of the keys. 20 the t 0 steps of the lever B areclearly shown. he step nearest the fulcrumbeing on the longitudinal key-line 4 and the step fartheraway from the center beingon'the For instance, in Fig. 139

, key-line 3,

.same manner.

a cac es if the key u were depressed it would project the pin the first distance, owing to the limited movement of the lever, but if the key y were depressed, it beingnearer the fulcrum, it would depress the lever the full distance, and consequently would project the pin the full distance. The same result would be obtained in operating the other levers, which are arranged in substantially the The projected pins act upon what are hereinafter described as performing-rods, such as those marked L and L Figs. 1 and 21, for controlling the unit-feed of the carriage and the character-locating mechanism. Each of these performing-rods has two steps on its outer end to engage with the pins, the first step being in the path of the pins which are projected only the first distance and the other steps being in the pathof the pins which are projected the fulldistance. 1 It will be understood that by depressing a lever B it will act upon one or other of the pin rows D D to move the punch-carrier in a horizontal line. Thus the pins on the righthand pin-wheel E will move the punch-carrier in a direction at right angles to the line of movement caused by the projection of the pins D D on the left-hand pin-wheel E, so that it will be readily seen that asingle movement in one or the other direction will bring the characters on the vertical line above the center and the horizontal line on the right of the center, and by combining these movements we can bringany of the sixteen characters in the righthand upper space into position to be impressed upon the matrix-sheet.

We will describe these combination movements by referring to Fig. 20. If we depress the character p, it will act upon the levers B and B, as indicated insaid figure, as both of .these levers are under the key. Consequently a pin on an outer pin row of a pinwheel E will be projected thefirst distance and a pin on the second pin row D the first distance on the pin-wheel E. Consequently, as shown by the diagram Fig. 17, the punchcarrier will be lowered one distance through the medium of the pins on the pin-wheel E and moved horizontally to the left three distances through the medium of theprojected pin on the'pin-wheel E, thus combining the vertical and horizontal movements above alluded to in reference to the characters v and u.

We will now describe the mechanism by which the vertical reverse movement is given to the punch-carrierthat is, the movements by which all of the characters below the horizontal central line are raised to that line-so that if these movements combine with the direct horizontal movements all of the characters in the lower right-hand squane will be brought into the impressing position.- D are the pinsin the third row of a pin-wheel E, and these pins are what we term vertical reverse-pins that is, they operate upon mechanism to raise the punch-carrier so as to bring the character-punches that are below the central horizontal line in position on that line. These pins are operated through mechanism from the keys below the central horizontal line on the keyboard. On the journal of each lever B, under the said keys, is an arm F, which acts upon a shouldered rod F, connected to an arm F and a rock-shaft F extending across the machine and adapted to suitable bearings 10 At the opposite end of this rock-shaft F is an arm F to which is attached the rod F secured to one arm of the vertical reverse-striker C". This striker is in line with the pins D in the third pin row. Consequently'any movement of the keys below the central horizontal line will cause the striker to project one of the pins D. To illustrate this movement, we will, for instance, sclect a key on which is marked the (shown clearly in Fig. 21) and depress it, causing the levers B B, which cross each other at this point, to move and project their respective pins, the lever B projecting a pin D to the first distance on the second pinrow of the pin-wheel E and the lever B projecting a pin on the second pin row of the pin-wheel E. The lever B, being also connected with the mechanism for giving the vertical reverse motion to the punch-carrier through this mechanism, projects a pin-D on the third row of pins. Consequently when these pins act in unison upon the mechanism for actuating the punch-carrier the carrier is raised in a diagonal line toward the center, or, in other words, opposite the impressing-plunger.

It will be understood that the action of the two character-representing pins is the same as if the character represented were in the right-hand upper corner; but in order to bring the characters below the central horizontal line into position there must necessarily be an additional movement, and this is accomplished by the vertical reverse-pin in the pin row D described above. Thus when these threesections are taken in conjunction they bring: the character-punch diagonally into position to be impressed into the matrixsheet.

We will now describe the movements of the horizontal reverse mechanism, which is actuated by any of the keys on the left of the central vertical "line. 1 -We will take as an'example the upper-case C. On the journals of each lever B, to the left of the center line, is secured an arm E, which acts upon the rod F giving it movement in the direction of the arrow, Fig. 21. This rod F is connected to onearm F of a bell-crank lever, the other arm F being connected to the link F which in turn is attached to the horizontal reverse striker (3 which projects a pin D in the fourth pin row in the wheel E, so that-when the key 0 is depressed it acts on the levers B B, as-shown clearly in Fig. 21; but as the horizontal reverse-striker is also connected to the lever B the character-punch will be moved downward and toward the right to the 

